A simplified process for flip-chip attachment of a chip to a substrate is provided by precoating the chip with an encapsulant underfill material having separate discrete solder columns therein to eliminate the conventional capillary flow underfill process. Such a structure permits incorporation of remeltable layers for rework, test, or repair. It also allows incorporation of electrical redistribution layers. In one aspect, the chip and pre-coated encapsulant are placed at an angle to the substrate and brought into contact with the pre-coated substrate, then the chip and pre-coated encapsulant are pivoted about the first point of contact, expelling any gas therebetween until the solder bumps on the chip are fully in contact with the substrate. There is also provided a flip-chip configuration having a complaint solder/flexible encapsulant understructure that deforms generally laterally with the substrate as the substrate undergoes expansion or contraction. With this configuration, the complaint solder/flexible encapsulant understructure absorbs the strain caused by the difference in the thermal coefficients of expansion between the chip and the substrate without bending the chip and substrate.
Legal claims defining the scope of protection, as filed with the USPTO.
1. An integrated, circuit and substrate assembly comprising: a) an electrical circuit substrate, b) an integrated circuit, coated with a first portion thermosetting polymer encapsulated said coated integrated circuit electrically interconnected to the electrical circuit substrate through solder bumps; and c) a hardened underfill encapsulant which comprises intermixed reaction products of (i) the first portion thermosetting polymer and (ii) a second portion, distinct first the first portion, comprising a fluxing agent, the underfill encapsulant being a hardened adhesive polymer, that chemically immobilizes the fluxing agent mid flux reaction byproducts such thaw the second portion does not appreciably degrade reliability of the integrated circuit assembly.
2. The integrated circuit and substrate assembly as in claim 1 wherein, the hardened adhesive polymer chemically immobilizes the flux reaction byproducts and the remainder of the fluxing agent and is sufficiently rigid such that the second portion encapsulant does not degrade reliability of the integrated circuit assembly to withstand thermal stresses.
3. The integrated circuit and substrate assembly as in claim 1 wherein the hardened adhesive polymer chemically immobilizes the flux reaction byproducts and the remainder of the fluxing agent such that the second portion encapsulant does not degrade reliability at the integrated circuit assembly to withstand corrosion.
4. The integrated circuit and substrate assembly as in claim 1 , wherein said thermosetting polymer comprises arm epoxy resin.
5. The integrated circuit and substrate assembly as in claim 1 wherein said thermosetting polymer encapsulant portion comprises a cured polymer component, a curing agent that promotes cure of said polymer component, and optionally, a filler component.
6. The integrated circuit and substrate assembly as in claim 5 , wherein said filter comprises a material having a coefficient of thermal expansion lower than a coefficient of thermal expansion of said thermosetting polymer.
7. The integrated circuit and substrate assembly as in claim 5 , wherein said filler comprises silica.
8. The integrated circuit and substrate assembly as in claim 1 , wherein said fluxing agent comprises an organic acid.
9. The integrated circuit and substrate assembly as in claim 1 , wherein said fluxing agent is cured by a chemical reaction with said thermosetting polymer.
10. The integrated circuit and substrate assembly as in claim 1 , wherein said fluxing agent is partially cured by a chemical reaction with said thermosetting polymer.
11. The integrated circuit and substrate assembly as in claim 10 , wherein said fluxing agent is partially cured by a chemical reaction with other than said thermosetting polymer.
12. The integrated circuit and substrate assembly as in claim 9 , wherein said fluxing agent is fully cured by a chemical reaction with said thermosetting polymer.
13. The integrated circuit and substrate assembly as in claim 9 , wherein said fluxing agent is an organic acid that polymerizes in the presence of said first portion.
14. The integrated circuit assembly of claim 1 wherein the underfill encapsulant includes a meltable portion adapted to allow removal of the integrated circuit front the electrical circuit substrate for repair or replacement.
15. The integrated circuit assembly of claim 1 wherein the encapsulant further includes a printed circuit layer having electrical circuitry thereon.
16. An integrated circuit and substrate assembly comprising; a) an electrically circuit substrate; b) an integrated circuit coated with a first portion thermosetting polymer encapsulant said coated integrated circuit electrically interconnected to the electrical circuit substrate through solder bumps; said integrated circuit adhered to said electrical circuit substrate through a hardened underfill composite which comprises reaction products of (i) the first portion thermosetting polymer and (ii) a second portion, distinct from the firm portion comprising a fluxing agent, said hardened composite underfill comprising i) a first thick portion having a first coefficient of thermal expansion and a first modulus; and ii) & second thin portion having a second coefficient of thermal expansion and a second modulus, wherein the first coefficient of thermal expansion is smaller than the second coefficient of thermal expansion.
17. The integrated circuit and substrate assembly as in claim 16 , wherein the hardened adhesive polymer chemically immobilizes the flux reaction byproducts and the remainder of the fluxing agent such that the second portion encapsulant does not degrade reliability of the integrated circuit assembly to withstand thermal stresses.
18. The integrated circuit and substrate assembly at in claim 16 , wherein she hardened adhesive polymer chemically immobilizes the flux reaction byproducts and the remainder of the fluxing agent such that the second portion encapsulated does not degrade reliability at the integrated circuit assembly to withstand corrosion.
19. The integrated circuit and substrate assembly as in claim 16 , wherein said thermosetting polymer comprises an epoxy resin.
20. The integrated circuit and substrate assembly as in claim 16 , wherein said thermosetting polymer encapsulant portion comprises a cured polymer component, a curing agent that promotes care of said polymer component, and optionally, a filler component.
21. The integrated circuit and substrate assembly as in claim 20 , wherein said filler comprises a material having a coefficient of thermal expansion lower than a coefficient of thermal expansion of said thermosetting polymer.
22. The integrated circuit and substrate assembly as in claim 20 , wherein said filler comprises silica.
23. The integrated circuit and substrate assembly us in claim 16 , wherein said fluxing agent comprises an organic acid.
24. The integrated circuit assembly of claim 16 , wherein the underfill encapsulant includes a meltable portion adapted to allow removal of the integrated circuit front the electrical circuit substrate for repair or replacement.
25. The integrated circuit assembly of claim 16 , wherein the underfill encapsulant further includes a printed circuit layer having electrical circuitry thereon.
Cooperative Patent Classification codes for this invention. Click any code to explore related patents in that topic.
March 19, 2003
August 10, 2004
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